Dataset Previews
First, initialize by adding tools and declare floating type
using GriddingMachine
using PkgUtility
using Plots
using Plots.PlotMeasures
ENV["GKSwstype"]="100";
FT = Float32;
# use this to fix the problem in generated preview.jl file
F1 = joinpath(@__DIR__, "../../Artifacts.toml");
F2 = joinpath(@__DIR__, "../../../Artifacts.toml");
GRIDDINGMACHINE_ARTIFACTS = (isfile(F1) ? F1 : F2);
predownload_artifact.(["CH_20X_1Y_V1", "CHL_2X_7D_V1", "CI_12X_1Y_V1",
"CI_PFT_2X_1Y_V1", "GPP_MPI_2X_1M_2005_V1",
"GPP_VPM_5X_8D_2005_V1", "LAI_4X_1M_V1",
"LM_ERA5_4X_1Y_V1", "LNC_2X_1Y_V1", "LPC_2X_1Y_V1",
"RIVER_4X_1Y_V1", "SIF740_TROPOMI_1X_1M_2018_V1",
"SLA_2X_1Y_V1", "TD_12X_1Y_V1", "VMAX_CICA_2X_1Y_V1",
"WD_2X_1Y_V1", "NPP_MODIS_1X_1Y"],
GRIDDINGMACHINE_ARTIFACTS);#=#=# ##O#- # ##O=# # #=#=-# # -#O#- # # -=#=# # # 0.4% # 1.6% #### 6.6% ################## 25.6% ####################################################################### 99.7% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # 0.0% 1.2% # 2.7% ###### 8.7% ####################### 32.1% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # -#O#- # # -=#=# # # -=O#- # # # 1.2% ##### 7.4% ######## 11.7% ########################### 38.1% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # -#O#- # # -=#=# # # # 2.0% #### 6.2% ################# 24.6% ################################################################# 91.4% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # 0.1% 0.6% # 2.1% ##### 7.4% ##################### 29.7% ########################################## 59.4% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # 0.1% 0.2% 0.6% # 2.0% ##### 7.4% ################## 26.2% ################################### 49.4% ################################################### 71.8% ################################################################### 93.2% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # -#O#- # # 0.2% 0.9% ## 3.5% ######### 13.7% ###################################### 53.7% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # 0.9% ######### 12.7% ################################# 46.0% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # ## 3.7% ######### 13.7% ########################################### 60.2% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # # 1.8% ############ 16.7% ####################################### 55.1% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # 0.3% 1.3% ## 4.0% ########## 15.2% ########################################## 59.3% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # 0.1% 1.1% ## 3.3% ######## 11.3% ############################## 43.0% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # 1.1% ######## 11.5% ############################################ 61.5% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # 0.1% 1.3% ### 4.6% ############# 18.8% ################################################### 72.1% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # ##### 7.2% ######################### 35.2% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # # 2.8% ####### 11.0% ################################ 45.0% ######################################################################## 100.0% #=#=# ##O#- # ##O=# # #=#=-# # -#O#- # # ###################### 30.9% ######################################################################## 100.0%
Then, define a function to plot the dataset
function preview_data(ds::GriddedDataset{FT}, ind::Int)
# preview data
return heatmap(view(ds.data,:,:,ind)',
origin="lower",
aspect_ratio=1,
xticks=[],
yticks=[],
c=:viridis,
size=(700,300),
framestyle=:none)
end
function preview_data(ds::GriddedDataset{FT}, ind::Int, clim::Tuple)
# preview data
return heatmap(view(ds.data,:,:,ind)',
origin="lower",
aspect_ratio=1,
xticks=[],
yticks=[],
c=:viridis,
clim=clim,
size=(700,300),
framestyle=:none)
endpreview_data (generic function with 2 methods)
Leaf level datasets
Leaf chlorophyll content
LCH_LUT = load_LUT(LeafChlorophyll{FT}());
mask_LUT!(LCH_LUT, FT[0,Inf]);
LCH_LUT = regrid_LUT(LCH_LUT, Int(size(LCH_LUT.data,2)/180));
anim = @animate for i ∈ 1:size(LCH_LUT.data,3)
preview_data(LCH_LUT, i, (0,80));
end
gif(anim, fps=5)Leaf nitrogen content
LNC_LUT = load_LUT(LeafNitrogen{FT}());
mask_LUT!(LNC_LUT, FT[0,Inf]);
LNC_LUT = regrid_LUT(LNC_LUT, Int(size(LNC_LUT.data,2)/180));
preview_data(LNC_LUT, 1)
Leaf phosphorus content
LPC_LUT = load_LUT(LeafPhosphorus{FT}());
mask_LUT!(LPC_LUT, FT[0,Inf]);
LPC_LUT = regrid_LUT(LPC_LUT, Int(size(LPC_LUT.data,2)/180));
preview_data(LPC_LUT, 1)
Specific leaf area
SLA_LUT = load_LUT(LeafSLA{FT}());
mask_LUT!(SLA_LUT, FT[0,Inf]);
SLA_LUT = regrid_LUT(SLA_LUT, Int(size(SLA_LUT.data,2)/180));
preview_data(SLA_LUT, 1)
Vcmax
VCM_LUT = load_LUT(VcmaxOptimalCiCa{FT}());
mask_LUT!(VCM_LUT, FT[0,Inf]);
VCM_LUT = regrid_LUT(VCM_LUT, Int(size(VCM_LUT.data,2)/180));
preview_data(VCM_LUT, 1)
Stand level datasets
Canopy height
CHT_LUT = load_LUT(CanopyHeightGLAS{FT}());
mask_LUT!(CHT_LUT, FT[0,Inf]);
CHT_LUT = regrid_LUT(CHT_LUT, Int(size(CHT_LUT.data,2)/180));
preview_data(CHT_LUT, 1)
Clumping index
# global clumping index
CLI_LUT = load_LUT(ClumpingIndexMODIS{FT}(), "12X", "1Y");
mask_LUT!(CLI_LUT, FT[0,1]);
CLI_LUT = regrid_LUT(CLI_LUT, Int(size(CLI_LUT.data,2)/180));
preview_data(CLI_LUT, 1, (0.4,1))
# global clumping index per PFT
CLI_LUT = load_LUT(ClumpingIndexPFT{FT}());
mask_LUT!(CLI_LUT, FT[0,1]);
CLI_LUT = regrid_LUT(CLI_LUT, Int(size(CLI_LUT.data,2)/180));
anim = @animate for i ∈ 1:size(CLI_LUT.data,3)
preview_data(CLI_LUT, i, (0.4,1));
end
gif(anim, fps=1)Gross primary productivity
# GPP MPI
GPP_LUT = load_LUT(GPPMPIv006{FT}(), 2005, "2X", "8D");
GPP_LUT = regrid_LUT(GPP_LUT, Int(size(GPP_LUT.data,2)/180));
mask_LUT!(GPP_LUT, FT[-100,Inf]);
anim = @animate for i ∈ 1:46
preview_data(GPP_LUT, i, (0,10));
end
gif(anim, fps=5)# GPP VPM
GPP_LUT = load_LUT(GPPVPMv20{FT}(), 2005, "5X", "8D");
GPP_LUT = regrid_LUT(GPP_LUT, Int(size(GPP_LUT.data,2)/180));
mask_LUT!(GPP_LUT, FT[-100,Inf]);
anim = @animate for i ∈ 1:46
preview_data(GPP_LUT, i, (0,10));
end
gif(anim, fps=5)Leaf area index
LAI_LUT = load_LUT(LAIMonthlyMean{FT}());
LAI_LUT = regrid_LUT(LAI_LUT, Int(size(LAI_LUT.data,2)/180));
anim = @animate for i ∈ 1:size(LAI_LUT.data,3)
preview_data(LAI_LUT, i, (0,6));
end
gif(anim, fps=1)Net primary productivity
NPP_LUT = load_LUT(NPPModis{FT}());
mask_LUT!(NPP_LUT, FT[-Inf,1e19]);
NPP_LUT = regrid_LUT(NPP_LUT, Int(size(NPP_LUT.data,2)/180));
NPP_LUT.data .*= 1e9;
preview_data(NPP_LUT, 1)
Sun induced fluorescence
SIF_LUT = load_LUT(SIFTropomi740{FT}(), 2018, "1X", "1M");
mask_LUT!(SIF_LUT, FT[-100,100]);
anim = @animate for i ∈ 1:12
preview_data(SIF_LUT, i, (0,3.5));
end
gif(anim, fps=3)Tree density
TDT_LUT = load_LUT(TreeDensity{FT}(), "12X", "1Y");
mask_LUT!(TDT_LUT, FT[0,Inf]);
TDT_LUT = regrid_LUT(TDT_LUT, Int(size(TDT_LUT.data,2)/180));
preview_data(TDT_LUT, 1, (0, 150000))
Wood density
TDT_LUT = load_LUT(WoodDensity{FT}());
mask_LUT!(TDT_LUT, FT[0,Inf]);
TDT_LUT = regrid_LUT(TDT_LUT, Int(size(TDT_LUT.data,2)/180));
preview_data(TDT_LUT, 1)
Land surface
Land elevation
ELE_LUT = load_LUT(LandElevation{FT}());
mask_LUT!(ELE_LUT, FT[0,Inf]);
ELE_LUT = regrid_LUT(ELE_LUT, Int(size(ELE_LUT.data,2)/180));
preview_data(ELE_LUT, 1)
Land mask
LMK_LUT = load_LUT(LandMaskERA5{FT}());
LMK_LUT = regrid_LUT(LMK_LUT, Int(size(LMK_LUT.data,2)/180));
preview_data(LMK_LUT, 1)
River flood plain height
FLD_LUT = load_LUT(FloodPlainHeight{FT}());
mask_LUT!(FLD_LUT, FT[0,Inf]);
FLD_LUT = regrid_LUT(FLD_LUT, Int(size(FLD_LUT.data,2)/180));
preview_data(FLD_LUT, 1)
River height
RVH_LUT = load_LUT(RiverHeight{FT}());
mask_LUT!(RVH_LUT, FT[0,Inf]);
RVH_LUT = regrid_LUT(RVH_LUT, Int(size(RVH_LUT.data,2)/180));
preview_data(RVH_LUT, 1)
River width
RVW_LUT = load_LUT(RiverWidth{FT}());
mask_LUT!(RVW_LUT, FT[0,Inf]);
RVW_LUT = regrid_LUT(RVW_LUT, Int(size(RVW_LUT.data,2)/180));
preview_data(RVW_LUT, 1)
River length
RVL_LUT = load_LUT(RiverLength{FT}());
mask_LUT!(RVL_LUT, FT[0,Inf]);
RVL_LUT = regrid_LUT(RVL_LUT, Int(size(RVL_LUT.data,2)/180));
preview_data(RVL_LUT, 1)
River manning coefficient
RVM_LUT = load_LUT(LandMaskERA5{FT}());
RVM_LUT = regrid_LUT(RVM_LUT, Int(size(RVM_LUT.data,2)/180));
preview_data(RVM_LUT, 1)
River unit catchment area
UCA_LUT = load_LUT(UnitCatchmentArea{FT}());
UCA_LUT = regrid_LUT(UCA_LUT, Int(size(UCA_LUT.data,2)/180));
preview_data(UCA_LUT, 1)
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